SITL: added InertialLabs simulator

This commit is contained in:
Andrew Tridgell 2023-12-01 15:57:21 +11:00
parent 54ffdc57f2
commit a17438d52c
3 changed files with 255 additions and 7 deletions

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@ -75,13 +75,6 @@ public:
// writing fix information to autopilot (e.g.)
virtual void publish(const GPS_Data *d) = 0;
protected:
uint8_t instance;
GPS &front;
class SIM *_sitl;
struct GPS_TOW {
// Number of weeks since midnight 5-6 January 1980
uint16_t week;
@ -90,6 +83,14 @@ protected:
};
static GPS_TOW gps_time();
protected:
uint8_t instance;
GPS &front;
class SIM *_sitl;
static void simulation_timeval(struct timeval *tv);
};

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@ -0,0 +1,124 @@
/*
This program is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 3 of the License, or
(at your option) any later version.
This program is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with this program. If not, see <http://www.gnu.org/licenses/>.
*/
/*
simulate InertialLabs external AHRS
*/
#include "SIM_InertialLabs.h"
#include <GCS_MAVLink/GCS.h>
#include "SIM_GPS.h"
using namespace SITL;
InertialLabs::InertialLabs() : SerialDevice::SerialDevice()
{
}
void InertialLabs::send_packet(void)
{
const auto &fdm = _sitl->state;
pkt.msg_len = sizeof(pkt)-2;
pkt.accel_data_hr.x = (fdm.yAccel * 1.0e6)/GRAVITY_MSS;
pkt.accel_data_hr.y = (fdm.xAccel * 1.0e6)/GRAVITY_MSS;
pkt.accel_data_hr.z = (-fdm.zAccel * 1.0e6)/GRAVITY_MSS;
pkt.gyro_data_hr.y = fdm.rollRate*1.0e5;
pkt.gyro_data_hr.x = fdm.pitchRate*1.0e5;
pkt.gyro_data_hr.z = -fdm.yawRate*1.0e5;
float sigma, delta, theta;
AP_Baro::SimpleAtmosphere((fdm.altitude+rand_float()*0.25) * 0.001, sigma, delta, theta);
pkt.baro_data.pressure_pa2 = SSL_AIR_PRESSURE * delta * 0.5;
pkt.baro_data.baro_alt = fdm.altitude;
pkt.temperature = KELVIN_TO_C(SSL_AIR_TEMPERATURE * theta);
pkt.mag_data.x = (fdm.bodyMagField.y / NTESLA_TO_MGAUSS)*0.1;
pkt.mag_data.y = (fdm.bodyMagField.x / NTESLA_TO_MGAUSS)*0.1;
pkt.mag_data.z = (-fdm.bodyMagField.z / NTESLA_TO_MGAUSS)*0.1;
pkt.orientation_angles.roll = fdm.rollDeg*100;
pkt.orientation_angles.pitch = fdm.pitchDeg*100;
pkt.orientation_angles.yaw = fdm.yawDeg*100;
pkt.velocity.x = fdm.speedE*100;
pkt.velocity.y = fdm.speedN*100;
pkt.velocity.z = -fdm.speedD*100;
pkt.position.lat = fdm.latitude*1e7;
pkt.position.lon = fdm.longitude*1e7;
pkt.position.alt = fdm.altitude*1e2;
pkt.kf_vel_covariance.x = 10;
pkt.kf_vel_covariance.z = 10;
pkt.kf_vel_covariance.z = 10;
pkt.kf_pos_covariance.x = 20;
pkt.kf_pos_covariance.z = 20;
pkt.kf_pos_covariance.z = 20;
const auto gps_tow = GPS_Backend::gps_time();
pkt.gps_ins_time_ms = gps_tow.ms;
pkt.gnss_new_data = 0;
if (packets_sent % gps_frequency == 0) {
// update GPS data at 5Hz
pkt.gps_week = gps_tow.week;
pkt.gnss_pos_timestamp = gps_tow.ms;
pkt.gnss_new_data = 3;
pkt.gps_position.lat = pkt.position.lat;
pkt.gps_position.lon = pkt.position.lon;
pkt.gps_position.alt = pkt.position.alt;
pkt.num_sats = 32;
pkt.gnss_vel_track.hor_speed = norm(fdm.speedN,fdm.speedE)*100;
Vector2d track{fdm.speedN,fdm.speedE};
pkt.gnss_vel_track.track_over_ground = wrap_360(degrees(track.angle()))*100;
pkt.gnss_vel_track.ver_speed = -fdm.speedD*100;
pkt.gnss_extended_info.fix_type = 2;
}
pkt.differential_pressure = 0.5*sq(fdm.airspeed+fabsf(rand_float()*0.25))*1.0e4;
pkt.supply_voltage = 12.3*100;
pkt.temperature = 23.4*10;
const uint8_t *buffer = (const uint8_t *)&pkt;
pkt.crc = crc_sum_of_bytes_16(&buffer[2], sizeof(pkt)-4);
write_to_autopilot((char *)&pkt, sizeof(pkt));
packets_sent++;
}
/*
send InertialLabs data
*/
void InertialLabs::update(void)
{
if (!init_sitl_pointer()) {
return;
}
const uint32_t us_between_packets = 5000; // 200Hz
const uint32_t now = AP_HAL::micros();
if (now - last_pkt_us >= us_between_packets) {
last_pkt_us = now;
send_packet();
}
}

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@ -0,0 +1,123 @@
//usage:
//PARAMS:
// param set AHRS_EKF_TYPE 11
// param set EAHRS_TYPE 5
// param set SERIAL4_PROTOCOL 36
// param set SERIAL4_BAUD 460800
// sim_vehicle.py -v ArduPlane -D --console --map -A --uartE=sim:ILabs
#pragma once
#include "SIM_Aircraft.h"
#include <SITL/SITL.h>
#include "SIM_SerialDevice.h"
namespace SITL
{
class InertialLabs : public SerialDevice
{
public:
InertialLabs();
// update state
void update(void);
private:
void send_packet(void);
struct PACKED vec3_16_t {
int16_t x,y,z;
};
struct PACKED vec3_32_t {
int32_t x,y,z;
};
struct PACKED vec3_u8_t {
uint8_t x,y,z;
};
struct PACKED vec3_u16_t {
uint16_t x,y,z;
};
struct gnss_extended_info_t {
uint8_t fix_type;
uint8_t spoofing_status;
};
struct gnss_info_short_t {
uint8_t info1;
uint8_t info2;
};
struct PACKED ILabsPacket {
uint16_t magic = 0x55AA;
uint8_t msg_type = 1;
uint8_t msg_id = 0x95;
uint16_t msg_len; // total packet length-2
// send Table4, 27 messages
uint8_t num_messages = 27;
uint8_t messages[27] = {
0x01, 0x3C, 0x23, 0x21, 0x25, 0x24, 0x07, 0x12, 0x10, 0x58, 0x57, 0x53, 0x4a,
0x3b, 0x30, 0x32, 0x3e, 0x36, 0x41, 0xc0, 0x28, 0x86, 0x8a, 0x8d, 0x50,
0x52, 0x5a
};
uint32_t gps_ins_time_ms; // ms since start of GPS week for IMU data
uint16_t gps_week;
vec3_32_t accel_data_hr; // g * 1e6
vec3_32_t gyro_data_hr; // deg/s * 1e5
struct PACKED {
uint16_t pressure_pa2; // Pascals/2
int32_t baro_alt; // meters*100
} baro_data;
vec3_16_t mag_data; // nT/10
struct PACKED {
int16_t yaw; // deg*100
int16_t pitch; // deg*100
int16_t roll; // deg*100
} orientation_angles; // 321 euler order
vec3_32_t velocity; // m/s * 100
struct PACKED {
int32_t lat; // deg*1e7
int32_t lon; // deg*1e7
int32_t alt; // m*100, AMSL
} position;
vec3_u8_t kf_vel_covariance; // mm/s
vec3_u16_t kf_pos_covariance;
uint16_t unit_status;
gnss_extended_info_t gnss_extended_info;
uint8_t num_sats;
struct PACKED {
int32_t lat; // deg*1e7
int32_t lon; // deg*1e7
int32_t alt; // m*100, AMSL
} gps_position;
struct PACKED {
int32_t hor_speed; // m/s*100
uint16_t track_over_ground; // deg*100
int32_t ver_speed; // m/s*100
} gnss_vel_track;
uint32_t gnss_pos_timestamp; // ms
gnss_info_short_t gnss_info_short;
uint8_t gnss_new_data;
uint8_t gnss_jam_status;
int32_t differential_pressure; // mbar*1e4
int16_t true_airspeed; // m/s*100
vec3_16_t wind_speed; // m/s*100
uint16_t air_data_status;
uint16_t supply_voltage; // V*100
int16_t temperature; // degC*10
uint16_t unit_status2;
uint16_t crc;
} pkt;
uint32_t last_pkt_us;
const uint16_t pkt_rate_hz = 200;
const uint16_t gps_rate_hz = 10;
const uint16_t gps_frequency = pkt_rate_hz / gps_rate_hz;
uint32_t packets_sent;
};
}